Apparatus and Method for Measuring Real Time Clock Accuracy in an Electric Meter

ABSTRACT

An arrangement for measuring an internal clock within an electricity meter includes an optical communication circuit within the meter, an optical detector external to the meter, and a frequency counter. The optical communication circuit within the electricity meter is operably coupled to receive a pulse output of the meter&#39;s internal clock, and is further configured to generate a corresponding optical pulse representative of the pulse output. The optical detector is configured to detect the pulse output via an optical port of the electricity meter. The frequency counter is operably coupled to receive from the optical detector a signal that is representative of the detected pulse output.

This application claims the benefit of U.S. Provisional PatentApplication Ser. No. 61/176,629, filed May 8, 2009, which isincorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to utility meters having processors thatemploy or rely upon clock circuits.

BACKGROUND

Electricity meters sometimes incorporate timing functions for billingmetrics. For example, timing functionality is useful in “time-of-use”metering where the rate for energy can change depending on the time ofday the energy is used. Meters employing time-of-use (“TOU”) meteringemploy a real time clock that is often based on a precision timingcrystal. Such meters are typically required to maintain the real timeclock through a power outage so that the billing schedule may resume ina proper state once power is restored.

The real time clock function can be maintained through a power outageusing an auxiliary power source such as a battery. Power outages,however, can create issues with real-time clock accuracy. In particular,when utility power is available in the meter (i.e. the normal case), thereal-time clock can self-calibrate or self-adjust based on the powerline signal, which is typically an accurate, 60 Hz signal. During apower outage, however, the precision source is not available and driftof the free-running real time clock is possible. Moreover, in someinternational markets, the power line signal may not have a reliable andprecise frequency.

There are industry standards for accuracy of the real time clock inutility meters. In particular, ANSI C12.1 2001 requirements for realtime clock accuracy are two (2) minutes per week or 200 ppm over atemperature range of 30° C. to 70° C. Some utilities require greateraccuracies such as 1 minute per month or 23 ppm at temperatures of 30°C. and 40° C. It is sometimes necessary to verify that the real-timeclock is operating within the defined parameters to ensure compliancewith the relevant standard.

Traditional methods of verifying clock accuracy are not alwaysconvenient as standards for clock accuracy become more restrictive. Forexample, prior methods tended to work fine when accuracy requirementswere broad such as 200 ppm. However, verifying clock accuracy whenlimits are in the range of 23 ppm resulted in lengthy measurement timesor complicated test setups that were not very practical in verifyingaccuracy on large numbers of meters. For example if a meter's clock canonly be read to a resolution of 1 second and it is desired to determineaccuracy to a resolution of 1 ppm, then the measurement time requiredwould be 1,000,000 seconds or 11.57 days.

It is also desirable to verify clock accuracy without removing the metercover or breaking the meter cover seal if one is used. Consequently, anonintrusive method of quickly verifying timing accuracy is desirable.If a method of measuring clock accuracy is sufficiently brief, it may bepractical to calibrate the meter's real-time clock during production ormanufacturing. Currently, the energy measurement function of the metercan be calibrated during manufacturing.

There is a need, therefore, for a method and/or apparatus that providesa more time-efficient clock measurement. There is also a need for such amethod that can be carried out without removing the meter cover.

SUMMARY

At least some embodiments of the present invention address theabove-referenced issues by determining clock accuracy using the opticalcommunication port of the meter.

One embodiment is an arrangement for measuring an internal clock withinan electricity meter that includes an optical communication circuitwithin the meter, an optical detector external to the meter, and afrequency counter. The optical communication circuit within theelectricity meter is operably coupled to receive a pulse output of themeter's internal clock, and is further configured to generate acorresponding optical pulse representative of the pulse output. Theoptical detector is configured to detect the pulse output via an opticalport of the electricity meter. The frequency counter is operably coupledto receive from the optical detector a signal that is representative ofthe detected pulse output.

Another embodiment of the invention is an arrangement within a utilitymeter that includes an optical communication circuit and a processingcircuit, both disposed within the meter housing. The processing circuitis operably coupled to selectively provide a clock output and ametrology circuit output to the optical communication circuit. In thiscase, the metrology circuit output is an output from a processingcircuit from the meter.

The above-described features and advantages, as well as others, willbecome more readily apparent to those of ordinary skill in the art byreference to the following detailed description and accompanyingdrawings.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a schematic diagram of an arrangement according to a firstexemplary embodiment of the invention;

FIG. 2 is a schematic diagram of an electricity meter according to asecond exemplary embodiment of the invention;

FIG. 3 is a flow diagram of a first exemplary set of operations of theprocessing circuit of the electricity meter of FIG. 2;

FIG. 4 is a flow diagram of a second set of operations of the processingcircuit of the electricity meter of FIG. 2; and

FIG. 5 show block diagrams of a meter optically connected to a meterprogramming unit and a frequency counter or frequency source inaccordance with embodiments of the invention.

DETAILED DESCRIPTION

FIG. 1 shows an exemplary embodiment of an arrangement 10 fordetermining the real-time clock accuracy in an electric utility meter.The arrangement 10 includes an optical communication circuit 14 disposedwithin a utility meter housing 16. The arrangement 10 also includes aprocessing circuit 15 disposed within the utility meter housing 16. Theprocessing circuit 15 is operably coupled to operably connect or providesignals from a clock output 12 and a metrology circuit output 17 to theoptical communication circuit 14.

The arrangement 10 in this embodiment also includes a test device 18.The test device 18 includes an optical communication circuit 20, afrequency counter circuit 22, and a display 24. The opticalcommunication circuit 20 may be an optical probe that is electricallycoupled to a self-contained frequency counter unit 23 that includes thefrequency counter circuit 22 and the display 24. Such self-containedfrequency counter units are known in the art.

The clock output 12 is operably coupled to a device or circuit, notshown in FIG. 1, that develops and maintains real-time clock informationwithin an electricity meter. Real-time clocks are known, and are knownto provide clock (e.g. day-time) information to metering circuitry, alsonot shown in FIG. 1, for time-of-use metering and other functions. InFIG. 1, the clock output 12 provides pulses that are generated based onthe time-keeping function of the real-time clock. In some cases, thetime-keeping function of a meter does not necessarily require or employa real-time clock. For example, if the meter is a demand-only type ofmeter, i.e. a meter that tracks highest periods of demand, and not atime of use type of meter, the timing function will be required to havesufficient interval timing accuracy but not necessarily “time of day”accuracy.

In any event, the clock output 12 is configured to provide a pulserepresentative of the time-base of the real-time clock and otherclocking functions. For example, the pulse output 12 a may include adirect output from a crystal oscillator, such as a nominally 32,768 Hzoscillator. Alternatively, the output may be a pulse otherwise generatedon a periodic basis, such as a pulse generated at a fraction of thenominal oscillator frequency. In another alternative, a pulserepresentative of a one-second time period (or longer) may be providedat the output 12. In the latter case, the pulse representative of onesecond may also be an adjusted or calibrated output of the real-timeclock 12. For example, if the real-time clock is based on an oscillatorof 32,768 Hz, and due to the manufacturing or other considerations, itis known that the oscillator actually operates at 32,755 Hz, then thereal-time clock may be calibrated to generate a one-second pulse forevery 32,755 output pulses of the oscillator. This calibrated one-secondpulse may be provided at the clock output 12. In this way, the accuracyof the calibrated real-time clock can be measured. More detail onobtaining the clock output is described below in connection with FIG. 2.

The metrology circuit output 17 is an output from the electricitymetering circuit, not shown, that generates energy consumptioninformation and or meter control information. The metrology circuitoutput 17 may suitably be the output calculations of a processingcircuit. The processing circuit may be part of the processing circuit15. (See, e.g. FIG. 2). The metrology circuit output 17 is configured togenerate signals for external communication of metering informationaccording to a meter communication protocol. Such metering informationmay include digital values representative of energy consumption, metercalibration information, or other meter information. Unlike the clockoutput 12, the metrology circuit output 17 does not merely provideperiodic clock pulses, but rather digital formatted data. In someembodiments, however, the metrology circuit output 17 may also generatepulses representative of energy consumption, wherein each pulserepresents an amount of energy consumed.

The processing circuit 15 includes a switch that is configured toselectively connect either the clock output 12 or the metrology circuitoutput 17 to the communication circuit 14. In one embodiment, theprocessing circuit 15 causes the metrology circuit 17 to be connected tothe communication circuit 14 absent a specific signal indicative of arequest to connect the clock output 12 to the communication circuit 14.The processing circuit 15 may suitably include a transistor switch orother device that physically or logically connects either the clockoutput 12 or the metrology circuit output 17 to the communicationcircuit 14. In one embodiment such as that shown in FIG. 2, the clockoutput the processing circuit 15, the metrology circuit output 17 areall housed in a single integrated circuit package, not shown. In such acase, the processing circuit 15 merely implements a firmware or softwareswitch to connect either the metrology circuit value or the clock pulseoutput to the output of the integrated circuit package that is connectedto the communication circuit 14.

The optical communication circuit 14 includes a device, such as a photodiode, that converts electrical signals into optical signals. Theoptical communication circuit 14 is located within the housing 16 suchthat it is proximate a transparent or translucent port 26 in the housing16. In this configuration, the optical communication circuit 14 isconfigured to communicate optical signals to devices external to thehousing 16.

Referring now to the test device 18, the optical communication circuit20 is a device configured to receive optical signals and convert thereceived signals into electrical signals. The optical communicationcircuit 20 may suitably comprise a phototransistor disposed proximate anoptical port 28. The optical communication circuit 20 is configured toprovide the electrical signals to a frequency counter circuit 22. of thetest device 18. The optical communication circuit 20 is generallycapable to detect pulses generated by the communication circuit 14 thathave been transmitted through the meter housing 16 when the opticalports 26 and 28 are disposed adjacent to each other. For example, bothof the optical communication circuits 14, 20 can include an IR opticaldetector and an IR optical transmitter.

The frequency counter circuit 22 is a circuit that is capable ofdetecting frequencies based on the period between successive pulses, anddisplaying them on the display 24, which is typically integrated in thesame housing. Such devices are known in the art, and include the 53131AUniversal Frequency Counter available from Agilent.

In ordinary operation of the meter, the test device 18 is not disposedas shown in FIG. 1. In most cases, nothing is connected to the opticalport 26 of the meter. However, from time to time, it may be desirablefor a technician to communicate data to or from the meter via theoptical port 26. To this end, it is known for the metrology circuit tocommunicate data with an external device, not shown, via the opticalport 26. This external device can be a portable computer or handheldcomputer, sometimes referred to as a meter programming unit, that can beused to extract metering data from the metrology circuit. In theembodiment of FIG. 1, this external device or meter programming unitwould include an optical probe that is disposed adjacent to the opticalport 26, similar to the manner in which the test device 18 is connected.

To communicate such metering data, the processing circuit 15 causes themetrology circuit output 17 to be connected to the communication circuit14. In some examples, the processing circuit 15 causes the metrologycircuit output 17 to be connected to the communication circuit 14responsive to an input requesting communications. The input requestingcommunications typically is received via an optical input circuit, notshown in FIG. 1, that is connected to the processing circuit 15. Whenthe metrology circuit output 17 is connected to the communicationcircuit 14, the metrology circuit output 17 may communicate meteringdata, either in the form of formatted digital data representative ofdata words or bytes, or in the form of a pulse train having a frequencythat is indicative of real time power consumption. Modes and types ofcommunication of data from a metrology circuit output 17 to an externalsource are known in the art.

In another operation, a technician or compliance inspector may use thetest device 18 to certify the accuracy of the real-time clock 12. Tothis end, the technician places the optical port 28 of the test device18 adjacent to the optical port 26 on the meter housing 16 as shown inFIG. 1. The processing circuit 15 then, responsive to a suitable inputvia circuits not shown in FIG. 1, connects the clock output 12 to thecommunication circuit 14. The clock output 12 provides electrical clockpulse signals to the optical communication circuit 14. The communicationcircuit 14 converts the received electrical pulses to optical pulses,such as infrared signal pulses. The optical communication circuit 14generates such pulses such that they radiate through the transparent ortranslucent optical port 26 of the meter housing 16.

The optical communication circuit 20 of the test device 18 receives theoptical clock pulse signal and converts the optical signals toelectrical clock pulse signals. The optical communication circuit 20provides the electrical clock pulse signals to the frequency counter 22.The frequency counter 22 operates in a known manner to develop aprecision frequency measurement representative of the frequency of thepulses, typically to a tolerance of 1 ppm. The frequency counter 22provides the developed frequency measurement to the display 24, or tosome other output, or to storage, not shown.

The technician may then compare the displayed frequency of the clockpulses on the test device 18 to the expected clock frequency for themeter. This comparison may be used to verify the accuracy of the clock,and/or determine whether the clock within the meter requires correction.The arrangement of FIG. 1 is thus capable of communicating clock pulsesvia an optical port, which allows for external verification via the useof a probe (e.g. elements 20/28) and a frequency counter device.Moreover, the arrangement of FIG. 1 employs an optical communicationcircuit 14 and port 26 already present in many meters.

Moreover, a typical frequency counter (e.g. counter 22) can generate anaccurate frequency measurement a manner of 1 to 10 seconds. By providinga means of determining real-time clock accuracy to a resolution of 1 ppmover a relatively short period of time such as 1 second or 10 seconds,meter manufacturers as well as electric utilities can determine quicklyand conveniently if a meter meets appropriate clock accuracyrequirements. If pulses are generated using the meter's optical port,clock accuracy can be determined quickly without removing the metercover. Clock accuracy could also be determined and calibrated when themeter is manufactured.

In addition to the invention described above it is possible for theprinted wiring board (“PWB”) assembler to measure the 32,768 Hzfrequency (to a resolution of 1 ppm) directly at the time the board isassembled using a fixture such as a “bed of nails” for retrieval laterin the manufacturing process or by the end user. The clock accuracycould then be stored in a data base and identified by a board assemblyserial number. The clock accuracy information could also be stored innon-volatile memory on the board itself for later retrieval. However,measuring the crystal frequency directly at the time the PWB isassembled may be undesirable if the act of measuring the crystalinfluences the crystal frequency. Also the temperature of the PWBassembly at the time the frequency is determined may not be the desiredtemperature for measuring clock accuracy. Providing a means ofdetermining clock accuracy via the optical port or option output isuseful if it is desired to confirm accuracy after a meter ismanufactured such as for testing at different temperatures or at acustomer's test lab or in the filed at a specific site or anytime clockaccuracy is questioned. Additionally, if the real time clock is derivedfrom line frequency instead of a crystal, line frequency accuracy can bedetermined in a similar fashion.

FIG. 2 shows in further detail an exemplary meter 100 according to afirst embodiment of the invention. The meter 100 includes a housing 105in which are disposed a metrology circuit 102, an optical communicationcircuit 104 and a clock circuit 106. The meter 100 also includesmemories 120, 121 and a display 130. The metrology circuit 102 furtherincludes a sensor circuit 110, an A/D conversion unit 112, and at leasta portion 115 a of a processing circuit 115. The clock circuit 106includes elements both external to and internal to the processingcircuit 115. Specifically, the clock circuit 106 includes an internalclock circuit 116 and an external clock circuit 117.

It will be appreciated that in the exemplary embodiment, the processingcircuit 115 is a commercially available chip package 113 that includesthe internal clock circuit 116, the A/D conversion unit 112, the memory120, and a set of output pins 119 and which is intended to be connectedto an external source of a clock reference frequency. The internal clockcircuit 116 includes elements that generate the clock information usedby the digital processing elements of the processing circuit 115, andfor the real-time clock maintained by the processing circuit 115. Theinternal clock circuit 116 may include at least a portion of anoscillator circuit, including for example, a phase-locked loop andvoltage controlled oscillator, not shown. The external clock circuit 117of the clock circuit 106 includes the source of the clock referencefrequency, specifically, a crystal resonator 150. Such elements areknown.

Referring now to the housing 105, the housing 105 may take any suitableform, and is generally configured to withstand a wide range ofenvironmental conditions. The housing 105 also provides at least someprotection against environmental conditions to the various elementsdisposed therein. Suitable housings for utility meters are well-known inthe art.

As discussed above, the metrology circuit 102 includes the sensorcircuit 110, as well as an A/D conversion unit 112 and the processingcircuit 115. The sensor circuit 110 in one embodiment includes voltagesensors and current sensors that are operably coupled to detect voltageand current signals representative of voltage and current provided to aload, and to generate measurement signals therefrom. In particular, themeasurement signals generated by the sensor circuit 110 are analogsignals each having a waveform representative of the voltage and currentprovided to the load. A suitable example of a voltage sensor includes avoltage divider that is operably coupled to the power lines. A suitableexample of a current sensor includes a current transformer that isdisposed in a current sensing relationship with the power line signal.These and other voltage and current sensors are known in the art.

The A/D conversion unit 112 may be any suitable analog-to-digitalconverter that is configured to sample the analog measurement signalsgenerated by the sensor circuit 110. The A/D conversion unit 112 isoperably coupled to provide the resulting digital measurement signals tothe processing circuit 115.

The processing circuit 115 includes a metrology portion 115 a that isconfigured to receive the digital measurement signals from the A/Dconversion unit 112 and generate energy consumption data therefrom. Tothis end, the metrology portion 115 a of the processing circuit 115includes digital processing circuitry that processes the digitizedmeasurement signals to thereby generate the energy consumption data.Such circuits are well known in the art. As is known in the art, theprocessing circuit 115 may also include the functions of a controller.To this end, the processing circuit 115 also suitably includes generalcontrol and supervisory processing circuitry, not shown in detail, butwhich would be known to those of ordinary skill in the art. Part of thiscontrol circuitry is a firmware switch 180, discussed further below. Theprocessing circuit 115 communicates information with external deviceswith serial input and output ports connected to output pins 119 of thechip package 113, as will be discussed further below.

Accordingly, the sensor circuit 110, the A/D conversion unit 112 andprocessing circuit 115 form the metrology circuit 102, which isconfigured to generate energy consumption data representative of energyused by the load. The processing circuit 115 also performs one or moreoperations that rely on a real-time calendar/clock.

The memory 120 of the chip package 113 includes one or more storagedevices of different types. The memory 120 may include volatile ornon-volatile RAM, EEPROM, or other readable and writeable memory device,any of which may be incorporated into the integrated circuit package113. The memory 120 stores instructions and/or parameters used by theprocessing circuit 115, and may further store energy consumption data.By contrast, the memory 121 is external to the chip package 113, andprovides for extended data storage. Such memory 121 would also, however,be located within the housing 105.

The optical communication circuit 104 is operably coupled to theprocessing circuit 115 via specific pins of the output 119. The opticalcommunication circuit 104 in this embodiment includes opticaltransmitter 160 and an optical receiver 165, both of which are locatedat a translucent or transparent optical port 170 of the meter housing105. The optical transmitter 160 is electrically coupled to a TX pin 119a of the chip package output 119, and the optical receiver is 165 iselectrically coupled to an RX pin 119 b of the chip package output 119.The optical transmitter 160 and the optical receiver 165 are thusconfigured to communicate data and other signals between the processingcircuit 115 and devices external to the meter housing 105. Such data caninclude energy consumption data, calibration data and the like. Inaccordance with some embodiments of the invention, the opticaltransmitter 160 is further configured to transmit clock signalsoptically to a device external to the meter 100. In other embodimentsdiscussed further below, the optical receiver 165 is further configuredto receive optical clock pulses from an external device for comparisonto an internal clock.

The display 130 is operably coupled to the processing unit 115 andprovides a visual display of information, such as information regardingthe operation of the meter 100. For example, the display 130 may providea visual display regarding the power measurement operations or energyconsumption data of the meter 100.

During normal operation, the metrology circuit 102 performs operationsto detect electrical signals on the power lines 101 and generatingmetering information therefrom. Such operations are known in the art.The internal clock circuit 116 and the external clock circuit 117 alsooperate to generate clock signals for the processing circuit 115 and theA/D conversion unit 112. The processing circuit 115 uses the clocksignal for execution of processing operations, as well as formaintaining a real-time calendar clock. The processing circuit 115 maysuitably use the real-time calendar clock to adjust utility cost ratesbased on time of day or time of year, as well as for other purposes.

The firmware “switch” 180 of the processing circuit 115 allows theoutput TX pin 119 a to controllably and alternatively receive dataand/or pulse signals from either the processing circuit 115 or the clock116. Accordingly, the firmware switch 180 may suitably include orcomprise programming that alternatively provides clock signals, whichare available within the chip package, or data signals (from themetrology function of the processing circuit 115), to the TX pin 119 a.

From time to time, the optical communication circuit 104 willcommunicate data with an external programming device, not shown, butwhich is known in the art, via the optical port 170. The data maysuitably be metering data. For example, the optical communicationcircuit 104 may communicate energy consumption information, calibrationdata, or configuration data between the metrology circuit 102 and theexternal programming device. FIG. 5A, discussed further below, shows ameter 100 connected this manner to a meter programming unit 504.

To transmit data, the firmware switch 180 is arranged to communicatedata from the metrology function of the processing circuit 115 to theoutput TX pin 119 a. The processing circuit 115 provides such data tothe output TX pin 119 a via the firmware switch 180. The opticaltransmitter 160 converts the data signals to optical signals andprovides the optical signals to an external device, not shown, via theoptical port 170. To receive data, the optical receiver 165 receivesoptical signals from the external device, converts the optical signalsto electrical signals, and provides the electrical signals to theprocessing circuit 115 via the RX port 119 b.

Accordingly, at least some embodiments of the present invention addressthe above-referenced issues regarding clock accuracy by using themeter's optical communication port 170 to verify the frequency of theinternal clock. Clock accuracy is determined by measuring a pulse outputwhere the timing between pulses is derived from the meter's internaltime clock. For example if the crystal oscillator 150 is a typical32,768 Hz watch crystal, pulses could be generated directly from themeter's internal clock at a rate of 32,768 Hz. Pulses could also begenerated at some fraction of the 32,768 frequency such as ½ or ¼ etc.In this embodiment, if a clock accuracy test is to be performed, theprocessing circuit 115 causes the firmware switch 180 to connect a clockoutput to the output pin TX 119 a. The clock pulses can then propagateto the optical transmitter 160, which transmits the pulses to anexternal device, such as a frequency counter, not shown, having its ownoptical probe.

FIG. 3 shows a first set of operations that may be performed by theprocessing circuit 115 to perform a test of clock accuracy according toa first embodiment of the invention. The first set of operations shownin FIG. 3 involve two external devices, shown in FIGS. 5A and 5B. Thetwo devices including a meter programming unit 504, which is known inthe art, and a frequency counter unit 506 similar to the frequencycounter unit 23 of FIG. 1.

Initially, the meter programming unit 504 is connected to the opticalport 170. To this end, the meter programming unit 504 includes or isconnected to an appropriate optical probe 502. In step 305, theprocessing circuit 115 establishes a serial connection with the meterprogramming unit 504 in any known or suitable manner. The establishmentof serial connection with the meter programming unit 504 will involvebidirectional transmission of handshaking data, among other things.Protocols for communications between metrology circuits and meterprogramming units are known in the art. As discussed above and shown inFIG. 2, the processing circuit 115 provides data to the external meterprogramming unit 504 via the firmware switch 180, the TX pin 119 a andthe optical transmitter 160. As also discussed above and shown in FIG.2, the processing circuit receives data from the external meterprogramming unit via the optical receiver 165 and the RX pin 119 b. Inthis embodiment, the RX pin 119 b need not be switched via the firmwareswitch 180.

After serial connection is established with the meter programming unit504, the processing circuit 115 may exchange meter data with the meterprogramming unit 504. Such metering data can include energy consumptioninformation, calibration data, configuration data, and programminginstructions. If the technician using the meter programming unit 504desires to test clock accuracy, the processing circuit 115 will receivefrom the meter programming unit 504 a digital signal representative of arequest for clock accuracy. (Step 310).

After step 310, the processing circuit proceeds to step 315. In step315, the processing circuit 115 connects the clock output to the outputTX pin 119 a via the firmware switch 180. Accordingly, after step 315,the optical transmitter 160 transmits only clock pulses through theoptical port 170. At that point, the technician may connect thefrequency counter 506 to the optical port 170 as illustrated in FIG. 5B.

The processing circuit 115, in the meantime in step 320, monitors the RXpin 119 b for a recognizable string of data. If, in step 325, theprocessing circuit 115 does not recognize a string of data at the RX pin119 b, the processing circuit 115 continues to produce clock signals atthe output TX pin 119 a. The RX pin 119 b will only receive arecognizable string when the test device is removed from the opticalport 170 and the meter programming unit is again coupled via the opticalport 170. Thus, when the technician has received a suitable measurement,the technician may remove the test device and reconnect the meterprogramming unit 504 (see FIG. 5A). This allows the technician to takeas much or as little time as necessary to obtain an adequate clockfrequency measurement.

When the meter programming unit 504 is reconnected, it will transmit arecognizable string to the processing circuit 115 via the opticalreceiver 165 and RX pin 119 b. In step 325, if the processing circuit115 recognizes the string, the processing circuit 115 proceeds to step340. In step 340, the processing circuit 115 reconnects its data outputto the TX pin 119 a via the firmware switch 180 to reestablish theserial communication connection with the meter programming unit 504.

FIG. 4 shows an alternative set of operations that may be used in analternative test configuration. In the alternative test configuration, asource of high accuracy clock pulses is coupled to the meter 100 via theoptical port 170. The processing circuit 115 then performs a test bywhich the received high accuracy pulses are compared to internallygenerated clock pulses to determine accuracy. In such an embodiment, thefirmware switch 180 is not necessary.

As discussed above, the alternative set of operations of FIG. 4 requirea source of high accuracy clock pulses. This source may simply replacethe frequency counter unit 506 of FIG. 5B, or may be implemented withina meter programming unit 504 itself. Such high accuracy pulse deviceswould be known to those of ordinary skill in the art.

In step 405, the processing circuit 115 receives a command to measureclock accuracy. Such a command can be received via serial datacommunications through the optical port, or using a reed switch or someother known device that provides simple command inputs to a meter. Afterstep 405, the processing circuit executes step 410.

In step 410, the processing circuit 115 connects the receive RX port 119b to an internal counter, not shown, referred to as the RX counter. Instep 415, the processing circuit 115 connects the clock 116 to anotherinternal counter, not shown, referred to as the clock counter. In step420, the processing circuit 115 resets or otherwise synchronizes starttimes and values for the RX counter and the clock counter and allows thecounters to accumulate pulses from the respective sources for apredetermined period of time.

Upon conclusion of the test, in step 425, the processing circuit 115obtains and compares the counts from the RX counter and the clockcounter. The difference between the obtained RX counter value and theobtained clock counter value is representative of the clock accuracyerror. In step 425, the processing circuit 115 calculates such error andcauses the error to be displayed, stored and/or communicate externally.

It will be appreciated that the test may be concluded in multiplealternative ways. For example, the test may conclude after apredetermined amount of time has passed (or predetermined number ofinternal or external clock cycles have been counted) since thesynchronization/start of step 420. In some case, the processing circuitwill continue to count pulses until the processing circuit 115determines that clock pulses are no longer being received. For example,the processing circuit 115 can monitor the input TX pin 119 a for arecognizable data string, signaling the end of the test. The test mayconclude if another external input is received, for example, through areed switch, or if external power is removed from the meter altogether.

In addition, in one alternative embodiment, the external source ofpulses may simply provide a pulse every second, or every n seconds. Insuch a case, the processing circuit 115 in step 420 would use only theinternal counter. The internal counter would would start accumulatinginternal clock pulses upon reception of one pulse on the RX pin 119 b,and then stop accumulating internal clock pulses upon reception of thenext pulse on the RX pin 119 b. The processing circuit 115 would thendetermine error by comparing the count of the internal counter to anexpected frequency value for the internal clock. For example, if theinternal clock has a nominal frequency or 32,768 Hz, then the number ofinternal clock pulses accumulated on the internal counter between twoconsecutive one-second pulses received on the RX pin 119 b should be32,768. Any difference would represent error. The processing circuit 115may suitably calculate this error as a percentage, display the detectedfrequency of the internal clock, or simply display the count.

Other methods of determining the coincidence, or conversely the error,between the internal clock and an external source of any frequency canbe implemented.

It will be appreciated that the above-describe embodiments are merelyexemplary, and that those of ordinary skill in the art may readilydevise their own implementations and adaptations that incorporate theprinciples of the present invention and fall within the spirit and scopethereof.

1. An arrangement for measuring a clock function within an electricitymeter, comprising: an optical communication circuit disposed within theelectricity meter, operably coupled to receive a pulse output of aninternal meter clock, and generate a corresponding optical pulserepresentative of the pulse output. an optical detector configured todetect the pulse output via an optical port of the electricity meter; afrequency counter operably coupled to the optical detector to receive asignal that is representative of the detected pulse output, thefrequency counter configured to generate a frequency valuerepresentative of a frequency of the detected pulse output based on thereceived signal.
 2. The arrangement of claim 1, wherein the opticalcommunication circuit and the internal meter clock are disposed within ameter housing.
 3. The arrangement of claim 1, wherein the test devicealso includes a display operably couled to the frequency counter, thedisplay configured to display the frequency value.
 4. The arrangement ofclaim 1, wherein the optical transmitter comprises a photo diode.
 5. Anarrangement within a utility meter, comprising: an optical communicationcircuit disposed within a utility meter housing, a processing circuitdisposed within the utility meter housing, the processing circuitoperably coupled to selectively provide a clock output and a metrologycircuit output to the optical communication circuit.
 6. The arrangementof claim 5, further comprising the metrology circuit, the metrologycircuit configured to generate a measurement of electricity consumption,wherein the metrology circuit output is representative of themeasurement of electricity consumption.
 7. The arrangement of claim 5,wherein the metrology circuit output comprises an energy consumptionmeasurement signal representative of energy delivered to a load.
 8. Thearrangement of claim 5, wherein the utility meter housing includes anoptical port, and wherein the optical communication circuit is arrangedto communicate optical signals through the optical port.
 9. Thearrangement of claim 5, wherein the processing circuit includes anoutput pin coupled to the optical communication circuit, and wherein theprocessing circuit is configured to selectively provide a clock outputand a metrology circuit output to the output pin.
 10. The arrangement ofclaim 9, wherein the utility meter housing includes an optical port, andwherein the optical communication circuit is arranged to communicateoptical signals through the optical port.
 11. The arrangement of claim10, further comprising the metrology circuit, the metrology circuitconfigured to generate a measurement of electricity consumption, whereinthe metrology circuit output is representative of the measurement ofelectricity consumption.
 12. A method comprising: a) transmitting datavia an optical port of an electricity meter; b) transmitting clockpulses via the optical port of the electricity meter; and c) performinga measurement relating to an internal clock of the electricity meterusing the clock pulses.
 13. The method of claim 12, wherein step b)further comprises transmitting clock pulses via the optical port andtransmitting no data via the optical port.
 14. The method of claim 12,wherein step c) further comprises performing the measurement to generatea measurement value of a frequency of the internal clock.
 15. The methodof claim 13, wherein step a) further comprises establishing serial dataconnection between a processing circuit of the electricity meter and anexternal processing device.
 16. The method of claim 15, wherein step b)further comprises: optically disconnecting the external processingdevice from the optical port; optically connecting a second device tothe optical port.
 17. The method of claim 16, wherein the second devicecomprises a frequency counting unit.
 18. The method of claim 16, whereinthe second device comprise a pulse generator configured to generate theclock pulses.
 19. The method of claim 18, wherein step c) furthercomprises using a processing circuit within the electricity meter toperform the measurement using the clock pulses.
 20. The method of claim19, wherein step c) further comprises using the processing circuit tocount internal meter clock pulses, and using the processing circuit toperform the measurement based on the clock pulses and the internal meterclock pulses.